Abstract
This paper presents the numerical simulation of the ultimate behaviour of 85 one-way and two-way spanning laterally restrained concrete slabs of variable thickness, span, reinforcement ratio, strength and boundary conditions reported in literature by different authors. The developed numerical model was described and all the assumptions were illustrated. ABAQUS, a Finite Element Analysis suite of software, was employed. Non-linear implicit static general analysis method offered by ABAQUS was used. Other analysis methods were also discussed in general in terms of application such as Explicit Dynamic Analysis and Riks method. The aim is to demonstrate the ability and efficacy of FEA to simulate the ultimate load behaviour of slabs considering different material properties and boundary conditions. The authors intended to present a numerical model that provides consistent predictions of the ultimate behaviour of laterally restrained slabs that could be used as an alternative for expensive real life testing as well as for the design and assessment of new and existing structures respectively. The enhanced strength of laterally-restrained slabs compared with conventional design methods predictions is believed to be due to compressive membrane action (CMA). CMA is an inherent phenomenon of laterally restrained concrete beams/slabs. The numerical predictions obtained from the developed model were in good correlation with the experimental results and with those obtained from the CMA method developed at the Queen's University Belfast, UK.
Highlights
It has been recognised for some time that laterally restrained slabs exhibit strengths in excess of those estimated by standard flexural and shear design methods [1,2]
The main objective of this paper is to demonstrate the ability and efficacy of FEA to simulate the ultimate load behaviour of slabs, including compressive membrane action (CMA), using ABAQUS FEA considering different boundary conditions, concrete strengths, span to depth ratios and reinforcement percentages
ABAQUS offers another broader analysis technique known as general static analysis which can be used to model most of the instability in structures
Summary
It has been recognised for some time that laterally restrained slabs exhibit strengths in excess of those estimated by standard flexural and shear design methods [1,2]. Rankin [6,7] developed a theory for arching action in slab strips and integrated this into his method for predicting punching failure in conventional unrestrained slabs to form an integrated approach to predicting the enhanced punching strength of laterally restrained slabs. Following this approach, Kirkpatrick, Rankin and Long [9] examined the enhancement due to CMA in bridge decks and produced a method for predicting the enhanced punching strength of bridge deck slabs. The findings of the research into CMA at Queen’s University Belfast up to this time were incorporated into the United Kingdom design manual for roads and bridges [13], ‘BD 81/02 - Use of Compressive Membrane Action in Bridge Decks’
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